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COURSE STRUCTURE & SYLLABUS OF
MASTER OF TECHNOLOGY (M.TECH)
In
Electrical Engineering
Course Structure
First Year
First Semester
Paper
Code
Subject Marks Credits
MFE1 Machine Drives 100 4
MFE2 Power Electronic Converter 100 4
MFE3 Control System 100 3
MFE4 EHV Transmission 100 3
MFE5-L Lab Practice 100 2
MFE1 : MACHINE DRIVES –I
1. CHARACTERISTICS OF THE ELECTRIC MOTORS
Introduction, Characteristics Of Dc Motors, Characteristic Of Three-Phase Induction Motor,
Variation Of Applied Voltage, Pole Change Motors, Slip Power Recovery Schemes,
Characteristics Of Synchronous Motors
2. DYNAMICS OF ELECTRIC DRIVES
Introduction, Classification Of Electric Drives, Basic Elements Of An Electric Drive,
Dynamic Conditions Of A Drive System, Stabili1y Considerations Of Electrical Drives
3. CONVERTERS FOR FEEDING ELECTRIC MOTORS
A General Survey Of Converters For Feeding Electric Motors, Phase Controlled Line
Commutated Converters
4. CONTROL OF ELECTRIC MOTOR
Induction motor drives, synchronous motor drives, dc drives.
5. CONTROL TECHNIQUES
Introduction, block diagram representation of drive systems, signal flow graph representation
of the systems, transfer functions, transient response of closed loop drive systems, frequency
response approach
Reference Books:
1. Power semi conductor controlled drives by G.K.Dubey
2. Fundamentals of Electrical Drives by G.K.Dubey
3. Electrical Machine & Power Electronics by P.C.Sen
4. Electrical Drives by S.A. Nasar
5. Power semi conductor controlled drives by G.K.Dubey
6. Fundamentals of Electrical Drives by G.K.Dubey
7. Electrical Machine & Power Electronics by P.C.Sen
8. Electrical Drives by S.A. Nasar
9. Power electronics and variable frequency drives by B. K. Bose
MFE2: POWER ELECTRONICS CONVERTERS - I
1. POWER SEMICONDUCTOR DIODES
Introduction, Diode Characteristics, Reverse Recovery Characteristics, Power Diode Types,
Effects Of Forward And Reverse Recovery Time, Series-Connected Diodes, Parallel-
Connected Diodes.
2. THYRISTORS
Introduction, Thyristor Characteristics, Two-Transistor Model Of Thyristor, Thyristor Turn-
On, Di/Dt Protection, Dv/Dt Protection, Thyristor Turn-Off, Thyristor Types, Series
Operation Of Thyristors, Parallel Operation Of Thyristors, Thyristor Firing Circuits,
Unijunction Transistor, Programmable Unijunction Transistor
3. CONTROLLED RECTIFIERS
Introduction, Principle Of Phase-Controlled Converter Operation, Single-Phase
Semiconverters, Single-Phase Full Converters, Single-Phase Dual Converters, Single-Phase
Series Converters, Three-Phase Half-Wave Converters, Three-Phase Semiconverters, Three-
Phase Full Converters, Three-Phase Dual Converters
4. THYRISTOR COMMUNICATION TECHNIQUES
Introduction, Natural Commutation, Forced Commutation, Commutation Circuit Design, Dc
Thyristor Spice Model, Commutation Capacitors
5. POWER TRANSISTORS
Introduction, Bipolar Junction Transistors, Power Mosfets, Sits, Igbts, Series And Parallel
Operation, Di/Dt And Dv/Dt Limitations, Isolation Of Gate And Base Drives
6. DC CHOPPERS
Introduction, Principle Of Step-Down Operation, Principle Of Step-Up Operation,
Performance Parameters, Chopper Classification, Switching-Mode Regulators, Chopper
Circuit Design
7. PROTECTION OF DEVICES AND CIRCUITS
Introduction, Cooling And Heat Sinks, Snubber Circuits, Reverse Recovery Transients,
Supply- And Load-Side Transients, Voltage Protection By Selenium Diodes And Metal-
Oxide Varistors, Current Protections
Reference Books:
1. Ned Mohan et. al: Power Electronics, John Wiley and Sons
2. P C Sen: Power Electronics, TMH
3. G K Dubey et. al: Thyristorised Power Controllers , Wiley Eastern Ltd.
4. B K Bose: Modern Power Electronics and AC Drives, Pearson
Edn(Asia)
MFE3 CONTROL SYSTEM
1: INTRODUCTION TO CONTROL SYSTEM
1.1 Classification Of Systems
1.2 Open-Loop Control System
1.3 Closed-Loop Control Systems
1.4 Elements Of Automatic Or Feedback Control System
1.5 Requirement Of Automatic Control Systems
2: MATHEMATICAL MODELS OF CONTROL SYSTEM
2.1 Representation of a Control System
2.2 Description of Some Of Typical Physics System
2.3 Tachnogenerators
2.4 Potentiometers, LVDT and Synchros
2.5 Synchros
2.6 Hydraulic Actuation
3: BASIC PRINCIPLES OF FEEDBACK CONTROL
3.1 The Control Objectives
3.2 Feedback Control System Characteristics
3.3 Proportional Mode of Feedback Control
3.4 Integral Mode Of Feedback Control
3.5 Derivatie Mode of Feedback Control
4: TIME DOMAIN ANALYSIS AND FREQUENCY RESPONSE
4.1 Standard Test Signals
4.2 Static Accuracy
4.3 Computation Of Steady State Errors
4.4 Transient Response: First Order System
4.5 Transient Response: Second Order System
4.6 Transient Response Specification
4.7 Conclusion
4.8 Frequency Response
4.9 Frequency Domain Specifications
4.10 Magnitude And Phase Angle Characteristics Plot
4.11 Frequency Response Specification
4.12 Representation Sinusoidal Transfer Function
5. CONCEPTS OF STABILITY AND THE ROUTH STABILITY CRITERION
5.1 Bounded-Input Bounded-Output Stability
5.2 Zero-Input Stability
5.3 The Routh Stability Criterion
6: NYQUIST STABILITY CRITERION
6.1 Stability Margin
6.2 Phase Margin
7: BODE PLOTS
8: ROOT LOCUS
8.1 The transfer function of a second order control system
8.2 GENERAL RULES
Reference Books:
1. K. Ogata, ‘Modern Control Engineering’, 4th edition, PHI, New Delhi, .
2. Norman S. Nise, Control Systems Engineering, 4th Edition, John Wiley, New Delhi,
3. Samarajit Ghosh, Control systems, Pearson Education, New Delhi,
4. M. Gopal, ‘Control Systems, Principles and Design’, Tata McGraw Hill, New Delhi,
MFE4 : EXTRA HIGH VOLTAGE (EHV) TRANSMISSION
1. HVDC POWER FLOW
Subscripts and symbols, Thyristor principle and control, Power conversion principle, Direct
Voltage Ud1 and Ud2, Power at Rectifier-end Pd1, Power at Inverter-end Pd2, Power loss in
DC system, Power in middle of HVDC line, Power at sending end, Power at receiving end,
General equations, Solved Numerical examples on Pd and Ud, Summary and Questions.
2. CONVERTER CONNECTIONS, RECTIFIER AND INVERTER WAVEFORMS
Rectifier Bridge Connections and Waveforms on AC and DC side, Six Pulse Bridge (Graetz
Bridge), 12-Pulse Bridge, Phase Control and Delay angle, Effect of Phase control on DC
Voltage, Valve Voltage, Inversion, Connections of Converter Bridge, Commutating
Reactance, Angle of Overlap Extinction Angle, Significance of Delay Angle and Extinction
Angle, Control of DC Voltage, Configuration of Bipolar 2T HVDC System, Valves and
Converters, Summary and Questions.
3. REACTIVE POWER COMPENSATION IN HVDC SUBSTATIONS
Reactive Power requirements of HVDC Converters, P.Q.S., Reactive Power Q required by
converter, and HVDC Substation, Reactive power equations, Effect of delay angle and
Extinction angle, Short Circuit Ratio (SCR), Impedance of AC Network, Equivalent short
circuit ratio, SCR in Planning of HVDC. Transient Voltage Rise, Summary and Questions.
4. MULTI-TERMINAL HVDC SYSTEMS
Two pole HVDC with earth return, substation poles in different locations, MTDC System
with series connected convertors, MTDC System with parallel connected converters, Control
of Parallel connected HVDBC System, Reversal of power in a terminal of HVDC System,
Three TDC System with parallel tapping , Two pole reversal in 3 TDC System, HVDC
Breakers in MTDC System, Applications of MTDC Systems, Worlds First Commercial 3
TDC System, World’s first 5 TDC System, Configuration and Type of HVDC System,
Summary and Questions.
5. INSULATION REQUIREMENT OF EHV – AC AND HVDC EQUIPMENT AND
TRANSMISSION LINES
Classification : Self restoring and Non-self restoring insulation, Insulation Design Aspects,
Stresses on Insulation , Tests, Causes of Flashover through Air and Gases, Insulation
withstand characteristics of Air Gaps, Leakage Distance or Creepage Distance of AC
Insulators, Leakage Distance or Creepage Distance of DC Insulators Line Insulator Design
with respect to Creepage Distance, Voltage Grading Rings (Collector Rings) to reduce
pollution, Grease or Petroleum Jelly to reduce flashovers, Electrolytic Action affecting pin
type DC Insulators. Effect of Wetting and contamination on leakage currents, Clearances
(Insulation Distance) for AC and HVDC, Clearances in HVDC Substations, Choice of
Clearance based on impulse withstand level, summary and questions.
6. ENGINEERING ASPECTS OF EHV – AC TRANSMISSION AND
TRANSMISSION PLANNING
Electrical, Mechanical and Thermal Design Aspects, Engineering Aspects of EHV AC
Transmission system, Transmission Planning and its co-relation with Generation Planning,
Distribution Planning, Why 400 kV AC was selected in India, Recent advances, Summary
and Questions.
7. ELECTROSTATIC FIELD AT GROUND LEVEL AND BIOLOGICAL
EFFECTS (EHV –AC AND HVDC)
Basic principles and terms in Electromagnetic Field theory, Significance of Electric Field
Intensity (Negative of Potential Gradient) at ground level, Electric field intensity of 3 phase
AC line at ground level beneath the conductors and at the edge of Row, Charging of Objects,
Vehicles and Human Body, Biological effects on Human Beings, Shock Effects of Electric
Field, Contact Currents, Limiting Values of 50 Hz Contact Currents, Summary and
Questions.
8. CORONA AND CORONA LOSSES (EHV – AC AND HVDC)
Principle of Corona, Emperical Formulae for Ec and Ecr, Terms and Definitions, Corona of
AC Overhead Lines, Factors affecting Corona, Conclusion of Research on Bad Weather
Corona, Corona Losses in AC Transmission, Variation in Corona Loss during one year,
factors affecting Corona Losses, Notations of terms in Derivations, Critical Surface Gradient,
Peek’s Law, Critical Disruptive Voltage and Critical Electric Stress for Visual Corona,
Corona Phenomenon with HVDC, Critical HVDC Voltage and Corona, Bipolar Corona Loss,
Influence of Weather on DC Corona Loss, Summary and Questions.
9. RADIO INTERFERENCE, TV INTERFERENCE AND AUDIBLE NOISE (EHV –
AC & HVDC) RADIO INTERFERENCE
Units of Measurement of RI, Generation of RI, propagation and Attenuation of RI,
Attenuation of RI waves, Radio Interference Field Strength against Distance, RI Design
Criterion for EHV AC Line, Signal to Noise Ratio (SNR), Broadcast Signal Strength, RI
Lateral Attenuation with Distance, RI at Edge of Row, Minimising RI and TVI, Bundled
Conductor for reducing Corona and RI, Evaluation of RI by Comparison Method & Semi
Analytical Method.
TV Interference: Comparison Formula for TVI Calculation of AC Lines RI and TVI
Calculation of AC Lines RI and TVI in HVDC Overhead Lines, Elimination of DC
Harmonics, RI from Bipolar HVDC Line, Comparision of RI from HVDC line and EHV AC
line TVI from HVDC Line.
Audible Noise : Terms and Defintions of Acoustics, Fundamentals of Sound, Measurement of
AN and weighting curves, Attenuation of Sound Pressure Level, Acceptable Level of Audible
Noise, Causes of AN in substation and Transmission Line, Audible Noisein Transformers and
reactors, Audible Noise in Transmission Lines, Limits of AN, Transmission Line Design
based on AN, Steps in Evaluating RN, Day and night equivalent of AN, Calculation and
Estimated AN of Transmission line, Sound Level of Transmission line, AN of HVDC line,
Summary and Questions.
Reference Books:
1. R.D. Begamudre, "Extra High Voltage AC Transmission Engineering "Wiley
Eastern
2. K.R Padiyar,"HVDC power transmission System, Technology and System
Reactions "new age international.
3. J Arrillaga,"High Voltage Direct current Transmission "IFFE Power Engineering
Series 6, Peter Peregrionus Ltd. London.
4. M.S Naidu & V.K Kamaraju "High Voltage Engineering "Tata Mc Graw Hill.
5. M.H Rashid,"Power Electronics: Circuit, Devices and Applications "Prentice hall
of India.
6. S .Rao, "EHV AC & HVDC Transmission Engineering and practice" Khanna
Publishers.
COURSE STRUCTURE & SYLLABUS OF
MASTER OF TECHNOLOGY (M.TECH)
In
Electrical Engineering
Course Structure
Second Year
Third Semester
Paper
Code
Subject Marks Credits
MSE1 Machine Analysis 100 4
MSE2 Optimal Control 100 4
MSE3 Advanced Control Theory 100 3
MSE4 Power System Protection 100 3
MSE5-L Lab Practice 50 2
MSE1 MACHINE ANALYSIS
1. ELEMENTS OF GENERALIZED THEORY
Essentials of Rotating Electrical Machines, Conventions, the Basic Two-Pole Machine, The
Per Unit System, Transformer With A Movable Secondary, Transformer And Speed Voltages
In The Armature, Kron's Primitive Machine, Analysis Of Electrical Machines
2. LINEAR TRANSFORMATIONS IN MACHINES
Invariance Of Power, Transformation From A Displaced Brush-Axis, Transformation From
Three Phases To Two Phases (A, B, C To A, , 0), Transformation From Rotating Axes (,
, 0) To Stationary Axes (D, Q, 0), Physical Concepts Of Park's Transformations,
Transformed Impedance, How To Apply Generalized Theory, Electrical Torque, Restrictions
Of The Generalized Theory Of Machines
3. ROTATING ELECTRICAL MACHINES IN QUASI HOLONOMIC REFERENCE
FRAME
The Generalised Machine Of The Hirst Kind, Generated Voltage, Impedance Matrix,
Impedance Matrix Of The Synchronous Machine, Inductance And Torque Matrices, The Flux
Linkage And The Flux Density Matrices, Rotation Matrix, Electromagnetic Torque,
Performance Calculations, Elimination Of Axes, Torque Matrix After Elimination Of Some
Axes, Analysis Using Revolving Field Theory, Transformation From The Stationary D-Q
Axes To Stationary Real Axes Reference Frame
4. ELECTRICAL MACHINES IN ROTATING REFERENCE FRAMES
Nonholonomic Reference Frame, Equation Of Voltage Along The General Rotating Axes,
Torque And Inductance Matrix In Nonholonomic Reference Frame, Holonomic Reference
Frame, Equation Of Voltage In Holonomic Reference Frame, Equation Of Torque In
Holonomic Reference Frame, Impedance Matrix Of The Second Generalised Machine From
The First Generalised Machine, Equation Of Voltage Of The First Generalised Machine
From That Of The Second, Equation Of Torque For The First Generalised Machine From
The Second One
5. INDUCTION MACHINE
Induction Machine In The Quasi-Holonomic Reference Frame, Two Phase Symmetrical
Components, Torque In A Two Phase Induction Machine, Single-Phase Induction Motor,
Capacitor Motor, Three Phase Induction Motor
6. SYNCHRONOUS MACHINE
Synchronous Generator In The Quasi Olonomicreference Frame, Power In The Synchronous
Machine, Reluctance Machine, Elimination Of The Field And Damper Windings,
Synchronous Machine Using Revolving Field Theory, Two Phase Alternator In Holonomic
Reference Frame, Transformation To The Real Axes Holonomic Reference Frame, Torque In
A Salient Pole Synchronous Machine, Determination Of The D-Axis And Q-Axis
Reactances, Synchronous Generator Under Sudden Short Circuit, Synchronous Generator
Without Dampers And Resistance, Generator Without Damper But With Field Resistance,
Generator With Damper Windings
7. ANALYSIS OF TRANSFORMERS
Bucking Impedance Of A Transformer, Steady State Analysis Of A Single Phase Core Type
Transformer, Three Phase - Y Transformer, Transient Analysis Of Transformers, Rectifier
Transformer, Parallel Operation Of Transformers, Measurement Of Bucking Impedances Of
Transformers, State Model Of Single Phase Transformer And Its Transient Analysis
8. TRANSFORMERS IN THE SEQUENCE REFERENCE FRAME
The Sequence Reference Frame, Impedance Matrixin The Sequence Reference Frame, Three
Phase -Y Transformer In The Sequence Reference Frame, Measurement Of Positive
Sequence Impedance, Measurement Of The Negative Sequence Impedance, Measurement Of
Zero Sequence Impedance, Delta-Star Transformer Under L-L-L Fault, Delta Star
Transformer Under L-L Fault, Delta Star Transformer Under L.L.G Fault When The Third
Phase Is Open
Reference Books: 1. D.P.Kothari and I.J.Nagrath, ‘Basic Electrical Engineering’, Tata McGraw Hill publishing
company ltd, second edition, 2002.
2. C.L. Wadhwa, ‘Electrical Power Systems’, Wiley eastern ltd India, 1985.
3. S.K.Bhattacharya, ‘Electrical Machines’, Tata McGraw Hill Publishing company ltd, second
edition, 1998.
4. V.K.Mehta and Rohit Mehta, ‘Principles of Power System’, S.Chand and Company Ltd, third
edition, 2003.
MSE2 OPTIMAL CONTROL
1. THE STANDARD REGULATOR PROBLEM-1
A Review Of The Regulator Problem, The Hamil Ton-Jacobi Equation, Solution Of The
Finite-Time Regulator Problem, Discrete Time Systems
2. THE STANDARD REGULATOR PROBLEM-II
The Infinite-Time Regulator Problem, Stability Of The Time-Invariant Regulator,
Summary And Discussion Of The Regulator Probl.Em Results, Cross-Product Terms And
Second Variation Theory, Regulator With A Prescribed Degree Of Stability
3. PROPERTIES OF REGULATOR SYSTEMS
The Regulator From An Engineering Viewpoint, Return Difference Equality And Related
Formulas Some Classical Control Ideas: Sensitivity , Comple Mentary Sensitivity, And
Robustness; Gain Margin, Phase Margin, And Time-Delay Tolerance, Insertion Of
Nonlinearities, The Inverse Optimal Control Problem
4. ASYMPTOTIC PROPERTIES AND QUADRATIC WEIGHT SELECTION
Single Input Systems, Mul Tivariable Systems, Further Issues In Q, R Selection
5. STATE ESTIMATOR DESIGN
The Nature Of The State Estimation Problem, Deterministic Estimator Design, Statistical
Estimator Design ( The Kalman-Bucy Filter )
6. SYSTEM DESIGN USING STATE ESTIMATORS
Controller Design-Basic Versions and Variations, The Separation Theorem And Performance
Calculation, Loss Of Passband Robustness With Observers, Loop Recovery, Robustness
Improvement Via Residual Feedback
7. FREQUENCY SHAPING
Blending Classical and Linear Quadratic Methods, State Estimate Feedback With Frequency
Shaping, Proportional Plus Integral State Feedback, Proportional Plus Integral State Estimate
Feedback
Reference Books:
1. Optimal Control Theory: An Introduction Donald E. Kirk
2. OPTIMAL CONTROL AND ESTIMATION a book by Robert F. Stengel
3. Optimal Control with Engineering ApplicationsGeering, Hans P.
MSE3 ADVANCED CONTROL THEORY
1. INTRODUCTION TO CONTROL SYSTEM
What is Control System, Classification Of Systems, Open-Loop Control System, Closed-
Loop Control Systems, Elements Of Automatic Or Feedback Control System, Requirement
Of Automatic Control Systems, Representation Of A Control System, Mathematical Models
Of Control System
2. TIME DOMAIN ANALYSIS AND FREQUENCY RESPONSE
Introduction, Standard Test Signals, Static Accuracy, Computation Of Steady State Errors,
Transient Response: First Order System, Transient Response: Second Order System,
Transient Response Specification, Conclusion, Frequency Response, Frequency Domain
Specifications, Magnitude And Phase Angle Characteristics Plot, Frequency Response
Specification
3. DESIGN AND COMPENSATION TECHNIQUES
Introduction, Luminary Design Considerations, Lead Compensation, Lag Compensation,
Lag-Lead Compensation, Tuning Rules for Pid Controllers
4. DESCRIBING-FUNCTION ANALYSIS OF NONLINEAR CONTROL SYSTEMS
Introduction to Nonlinear Systems, Nonlinear Control Systems, Describing Function,
Describ1ng-Function Analysis Of Nonlinear Control Systems, Concluding Comments
5. ANALYSIS OF CONTROL SYSTEMS IN STATE SPACE
Introduction, Basic Materials In State-Space Analysis, Transfer Matrix, Controllability,
Observability, Obtaining State-Space Equations In Canonical Forms, Liapunov Stability
Analysis, Liapunov Stability Analysis Of Linear Time-Invariant Systems, Time-Varying
Systems
6. DESIGN OF CONTROL SYSTEMS BY STATE-SPACE METHODS
Introduction, Control System Design Via Pole Placement, Design Of State Observers
Reference Books:
1. Modern Control Engineering – by K. Ogata, Prentice Hall of India, 3rd edition, 1998
2. Control Systems Engineering by I.J. Nagarath and M.Gopal, New Age International (P) Ltd.
3. Digital Control and State Variable Methods – by M. Gopal, Tata Mc Graw-Hill Companies, 1997
4. Systems and Control by Stainslaw H. Zak , Oxford Press, 2003.
MSE4 POWER SYSTEM PROTECTION
1. INTRODUCTION
Need for Protective Systems, Nature and Causes of Faults, Types of Faults, Effects of Faults ,
Fault Statistics, Evolution of Protective Relays, Zones of Protection, Primary and Back-up
Protection, Essential Qualities of Protection, Classification of Protective Relays,
Classification of Protective Schemes, Automatic Reclosing , Current Transformers for
Protection , Potential Transformer , Summation Transformer, Phase-sequence Current-
segregating Network, Basic Rely Terminology ,
2. OPERATING PRINCIPLES AND RELAY CONSTRUCTION.
Electromagnetic Relays, Thermal Relays, Static Relays, and Microprocessor-based protective
Relays
3. OVERCURRENT PROTECTION
Time-current Characteristics, Current Setting, Time Setting , Overcurrent Protective Schemes
, Reverse Power or Directional Relay, Protection of Parallel Feeders , Protection of Ring
Mains , Earth Fault and Phase Fault Protection, Combined Earth Fault and Phase Fault
Protective Scheme , Phase Fault Protective Scheme , Directional Earth Fault Relay, Static
Overcurrent Relays, Microprocessor-based Overcurrent Relays .
4. DISTANCE PROTECTION
Impedance Relay, Reactance Relay, MHO (Admittance or Angle Admittance) Relay, Angle
Impedance (Ohm) Relay, Input Quantities for Various Types of Distance Relays, Sampling
Comparator, Effect of Arc Resistance on the Performance of Distance Relays, Effect of
Power Surges (Power Swings) on the Performance of Distance Relays, Effect of Line Length
and Source Impedance on Distance Relays, Selection of Distance Relays, MHO Relay with
Blinders, Quadrilateral Relay, Elliptical Relay, Restricted MHO Relay, Restricted Impedance
Relay, Restricted Directional Relay, Restricted Reactance Relay, Some Other Distance Relay
Characteristics, Swiveling Characteristics, Choice of Characteristics for Different Zones of
Protection, Compensation for Correct Distance Measurement, Reduction of Measuring Units,
Switched Schemes, Auto-reclosing,
5. AC MACHINES AND BUS-ZONE PROTECTION
Protection of Generators, Transformer Protection, Bus-zone Protection, Frame Leakage
Protection
6. MICROPROCESSOR AND INTERFACING
Introduction, Microprocessors, Input/Output Devices, Semiconductor Memories, Single Chip
Microcomputers, I/O Ports and Programmable Peripheral Interface, Programmable Interval
Timer (Intel 8253), IC Elements and Circuits for Interfaces, AID Converter, Analog
Multiplexer, SIR Circuit
7. MICROPROCESSOR-BASED PROTECTIVE RELAYS
Introduction, Overcurrent Relays, Impedance Relay, Directional Relay, Reactance Relay,
Generalised Mathematical Expression for Distance Relays, Measurement of R and X, Mho
and Offset Mho Relays, Quadrilateral Relay, Generalised Interface for Distance Relays,
Digital Relaying Algorithms, Differential Equation Technique, Discrete Fourier Transform
Technique, Walsh-Hadamard Transform Technique, Rationalised Haar Transform Technique
Removal of the dc Offset, Microprocessor Implementation of Digital Distance Relaying
Algorithms.
Reference Books:
1. H.J. Altuve, E. O Schweitzer, III, Modern Solutions for Protection, Control and Monitoring of
Electric Power Systems. Schweitzer Engineering Laboratories, Inc., 2010.
2. P.M. Anderson, Analysis of Faulted Power Systems,
3. P.M. Anderson, Power System Protection. IEEE PRESS, 1
COURSE STRUCTURE & SYLLABUS OF
MASTER OF TECHNOLOGY (M.TECH)
In
Electrical
Course Structure
Second Year
Fourth Semester
SPECIALIZATION 1
SPECIALIZATION 1: CONTROL & INSTRUMENTATION
MSCI 01 : Industrial Instrumentation And Control
Basic Concepts And Qualities Of Measurements, Electrical Measuring Instruments,
Displacement Force, Torque And Speed Measurement, Level Measurement, Pressure
Measurement, Flow Measurements, Temperature Measurement, Optical And Surveying
Instruments, Dimension Measurement, Measurement Of Physical Properties, Electronic
Measurement, Magnetic Measurements, Selection, Installation And Commissioning Of
Instruments, Process Control And Automatic Controllers, Transmitters, Telemetry Systems
And Recorders, Computer Aided Measurement And Control systems, Microcomputer Based
Measurement And Control Using Distributed Control System.
Specialization 1 CONTROL & INSTRUMENTATION Marks Credits Paper Code Subject
MSCI 01 Industrial Instrumentation and control 100 4 MSCI 02 Digital control and state variable methods 100 4 MSCI 03 Electronic Instruments and Systems 100 4 MS 04 Project 300 12
Reference Books:
1. Doebelin E. O, Measurement Systems: Application and Design, Fourth edition,
McGraw Hill, Singapore, 1992.
2. D Patranabis , Principle of Industrial Instrumentation , TMH publication.
3. Andrew W. G, Applied Instrumentation in Process Industries - A survey, Vol.1 &
Vol.2, Gulf Publishing Company, Houston, 1992.
4. Liptak B. G, Process Measurement and Analysis, Third edition, Chilton Book
Company, Pennsylvania, 1995.
5. Considine D. M, Process Instruments and Control Handbook, Fourth edition, McGraw
Hill, Singapore, 1993
6. R.K. Jain, Mechanical and Industrial Measurements, Tenth edition, Tata McGraw
Hill, New Delhi, 1996.
7. Spitzer D.W., Industrial flow measurement, Second edition, ISA
MSCI 02: Digital Control and State Variable Methods
Introduction, Signal Processing In Digital Control, Models Of Digital Control Devices And
Systems, Design Of Digital Control Algorithms, Control System Analysis Using State
Variable Methods, State Variable Analysis Of Digital Control Systems, Pole Placement
Design And State Observers, Lyapunov Stability Analysis, Linear Quadratic Optimal
Control, Nonlinear Control Systems, Neural Networks For Control, Fuzzy Control.
Reference Books:
1. Andrew W. G, Applied Instrumentation in Process Industries - A survey, Vol.1 & Vol.2, Gulf
2. Liptak B. G, Process Measurement and Analysis, Third edition, Chilton Book Company, Pennsylvania,
1995.
3. Considine D. M, Process Instruments and Control Handbook, Fourth edition, McGraw Hill, Singapore,
1993
4. R.K. Jain, Mechanical and Industrial Measurements, Tenth edition, Tata McGraw Hill,
5. Spitzer D.W., Industrial flow measurement, Second edition, ISA press, New york, 1990.
6. Spitzer D.W., Flow measurement, ISA press, New york, 1998.
MSCI 03: Electronic Instruments and Systems
Modern Electronic Equipment And Maintenance Concepts, Maintenance Aids And Records,
Trouble Shooting And Repair Procedure, Soldering And Desoldering Techniques,
Measurement Concepts And Techniques, Measuring Instruments, Passive Components,
Active Components, Operational Amplifiers, Digital Circuits, Troubleshooting In Power
Supply Units, Troubleshooting In Measuring Instruments, Troubleshooting In Audio
Systems, Trouble Shooting In Radio Communication Equipment, Troubleshooting In Video
Systems, Troubleshooting In Computes, Home And Office Electronic Systems, Installation
And Safety Measures, Preventive Maintenance.
Reference Books:
1. B.M.Oliver and J.M.cage, ‘Electronic Measurements & Instrumentation’, McGraw
Hill International Edition, 1975.
2. Joseph. J. Carr, ‘Elements of Electronic Instrumentation & Measurements’, III
edition, Pearson Education, 2003.
3. C.S. Rangan, G.R. Sarma, V.S.V. Mani, ‘Instrumentation Devices & Systems’, Tata
McGraw Hill, 2002.
4. D. A. Bell, ‘Electronic Instrumentation and Measurements’, Prentice Hall of India,
2002.
5. Rajendra Prasad, ‘Electronic Measurements and Instrumentation’, Khanna Publishers,
Delhi, 2003.
6. B.R. Gupta, ‘Electronics and Instrumentation’, S. Chand Co. (P) Ltd., Delhi, 2003.
MS 04: PROJECT
Project Guidelines:
Thinking up a Project
You are expected to come up with your own idea for a project. A wide range of topics is
acceptable so long as there is substantial computing content and project is predominantly of a
practical, problem-solving nature. You might take up an interest which you already have in
your stream of engineering. You may do your project in any reputed organization or a
department. Every student is to take up a project individually. The project is a vehicle for you
to demonstrate the required level of competence in your chosen field of Masters.
Start thinking about your project right in the beginning. If you want to do the project in
industrial environment start your correspondence fairly early to find an organization, which is
ready to accept you You must submit an outline of your project (two or three pages) to your
guide within one month of start of the project work. This must include the Title, Objective,
Methodology (main steps to carry out a project), expected output and organization where you
intend to carry out the project.
Arranging a Guide
When you have an idea of your project, even a tentative one, approach a suitable person who
has interest and expertise in that area. The Guide may be a person with M.E. / M.Tech with a
five-year working experience or a B.E./ B.Tech having a working experience of fifteen years
in relevant field.
Working with the Guide
The Guide’s role is to provide support and encouragement to direct the student’s attention to
relevant literature, to provide technical assistance occasionally, to read and comment on the
draft report and to give guidance on the standard and amount of work required. The Guide is
not responsible to teach any new skills and language required for project work or for
arranging any literature or equipment. You are expected to meet at least once a month to your
Guide. Rest you can workout your own arrangement. The students, who are content to carry
out their work largely without supervision, should keep their Guide in touch with what they
are doing. A student should not remain silent for months and then appear with a complete
project work unknown to supervisor. In such circumstances, the Guide cannot be counted on
to give an automatic seal of his approval. If a project produces a piece of software, the Guide
would normally expect to see a demonstration of the software in action.
The main purpose of the report is to explain what you did in your project. The reader should
be able to see clearly what you set out to do and what you achieved. It should describe the
problem addresses and explain why you tackled it in the way you did. It should include your
own assessment of how successful the project was.
Resist temptation to include pages of padding. If the project consists of developing an
application in area with which a computer scientist would not be familiar – such as chemical
testing, stock & shares – it might be necessary to include some explanatory company/
organization profile for whom you have done the work must not appear in chapters and must
go to appendix part.
The work that is presented for examiners should be your own. The presentation of another
person’s work, design or program as though they are your own is a serious examination
offence. Direct quotation form the work of others (published or un published) must always be
clearly identified as such by being placed in quotation marks, it is essential that reader should
be able to see where the other work ends and your begins.
Sometimes a project containing good work is marred by a report, which is turgid, obscure and
simply ungrammatical. In such cases, it is very difficult to find out the work done during the
project. An examiner cannot be kind enough to look properly on a project that is almost
unreadable.
Some important points for carrying out a project
1. The organizations or companies offer you a placement for project work out of good
will or to get some useful work done. Usually the companies do not provide you
everything required by you. You must settle this right in the beginning of the project
with the business that what will you get from them and what you have to arrange
yourself.
2. Some times a complication arises due to the fact that some aspect of your project
work is considered confidential by the company. If this is so, it is your responsibility
to get whatever clearance is necessary from the organization right in the beginning as
essential parts like system analysis and design, flow charts etc. can not be missing
from a project report.
3. Make sure you allow enough time for writing report. It is strongly recommended that
do some writing work as you carry out the project rather than leaving write up until
the end. You must allow at least a month to finally write the report. There has to be
enough time for the supervisor to read and comment on it and for student to make
changes (sometimes extensive) on the basis of the comments. You may have to
prepare two or three drafts before the final submission. Remember that it is mainly the
project reports that get examined. An external supervisor receives a pile of project
reports written by people who he does not know. If a project produced some software
he even may not get time to see it running. In most cases he forms his judgment
purely on the basis of the report. Please make your report as readable as possible
content wise as well as presentation wise.
a. Introduction: This must contain background, any previous work done in the area
of your project, your objective and other relevant material that may be helpful to
further explain your project work.
b. The existing system: The study of the present system; problems in existing
system.
c. System design: The proposed system; Any specific problem encountered at how
you handled them.
d. Implementation of the system: Implementation issues and their justification.
e. Conclusions: Any shortcoming; your assessment of your work; comparison of
your work with similar works; silent features of your work any feature
modification. Real times applications of your project work.
References must be given at the end following any standard way of giving references.
For example:
Langdrof, ‘Theory of Alternating Current Machinery” Tata McGraw Hill, July 2003.
Finally, your project work is your brainchild and nobody knows about it more than you. Be
confident to explain your work at the time of viva and be honest to accept any short falls.
The Project Report Details
The report should be prepared with the Word Processing software. They should be printed on
A4 size (Executive Bond) paper. A margin of 1.5 inches must be allowed on left hand side
for binding. The pages should be numbered. The report should be typed in the 12-font size
with vertical spacing of 1.5. You must submit three copies of your Project Report in
between 15.06.05 and 20.06.05 positively along with a brief Bio –Data of the Supervisor.
A report should be hard bound (light green cover with golden print on the cover). The title of
the project should be clearly visible on the cover.
The cover page should be as figures below. The first page should be title page containing the
title, the candidates name, Enrolment Number, Name of Study Centre and University. Second
page is a certificate from the supervisor. The 3rd page is for the acknowledgement. Fourth
page gives the contents of the project report. Fifth page should be an abstract of the project
followed by the chapters. You must ensure that all pages are legible. Where the project has
produced software for a personal computer, you should include a CD inside the back cover of
the report, along with instructions in the report how to run it
Reference Books:
Cover Page Project Title
A Project Report
Submitted in partial fulfillment of the degree of Master of
Technology Supervisor’s Student’s Name Name Karnataka State Open University, Mysore.
(Year) LOGO
Certificate by Supervisor
2
Acknowledgment
3
Contents
4
Abstract
5
J. Endreny, Reliability Mode
J. Endreny, Reliability Mode
COURSE STRUCTURE & SYLLABUS OF
MASTER OF TECHNOLOGY (M.TECH)
In
Electrical
Course Structure
Second Year
Fourth Semester
SPECIALIZATION 2
SPECIALIZATION 2 : POWER SYSTEM CONTROL
MSPS 01 : Electrical Power System Design
Constants Of Overhead Transmission Lines, Characteristics And Performance Of
Transmission Line, Design Of Transmission Lines, Power System Operation And Analysis,
Switchgear, Design Of EHV Transmission Lines, High Voltage DC Transmission Lines,
Design Of Power System, Power System Control And Line Compensation, Design Of
Distribution Systems, Economics Of Distribution Systems, Power System Improvement,
Power System Planning.
Specialization 2 POWER SYSTEM CONTROL Marks Credits
Paper Code Subject MSPS 01 Electrical Power System Design 100 4 MSPS 02 Power System Analysis and
Dynamics 100 4
MSPS 03 Power System Reliability 100 4 MS 04 Project 300 12
Reference Books:
1 Electrical Power Systems - C.L.Wadhwa
2 Modern Power System Analysis - Nagrath & Kothari
3 Fundamentals of power system protection - Y.G.Paithankar & S.R.Bhinde
4 Power System Protection - Badriram & Vishwakarma
5 Power System Protection & Switchgear - Ravindranath & Chander
MSPS 02 : Power System Analysis And Dynamics
Introduction, network formulation, power system components and their representation, short
circuit studies, numerical solution of mathematical equations, load flow studies, economic
load scheduling of power system, sparsity technique, dynamic analysis and modeling of
machines, stability studies, multiphase( 6 phase) systems, protective relaying, digital relaying
schemes.
Reference Books:
1. W.D. Stevenson, Jr. “Elements of Power System Analysis”, Mc Graw Hill.
2. C.L. Wadhwa, “Electrical Power System”, New Age International.
3. Chakraborthy, Soni,Gupta & Bhatnagar, “Power System Engineering”, Dhanpat Rai
& Co.
4. T.K Nagsarkar & M.S. Sukhija, “Power System Analysis” Oxford University Press,
2007.
5. L. P. Singh; “Advanced Power System Analysis & Dynamics”, New Age
International
6. Hadi Sadat; “Power System Analysis”, Tata McGraw Hill.
7. D.Das, “Electrical Power Systems” New Age International, 2006.
8. J.D. Glover, M.S. Sharma & T.J.Overbye, “Power System Analysis and Design”
Thomson, 2008.
9. P.S.R. Murthy “Power System Analysis” B.S. Publications, 2007.
10. Stagg and El-Abiad, “Computer Methods in Power System Analysis” Tata Mc Graw
Hill
11. Kothari & Nagrath, “Modern Power System Analysis” Tata Mc. Graw Hill.
MSPS 03: power system reliability
Introduction, review of probability theory and stochastic processes, analytical methods of
reliability modeling and calculations, Monte Carlo simulation method, generation system
reliability, multiarea system reliability, composite system reliability evaluation, distribution
system reliability.
Reference Books:
1. J. Endreny, Reliability Modeling in Electric Power Systems, John Wiley & Sons.
2. Billinton & Ronald, N allan, Reliability Evaluation of Power Systems, Plenum Press,
New York.
MS 04 : PROJECT
Project Guidelines:
Thinking up a Project
You are expected to come up with your own idea for a project. A wide range of topics is
acceptable so long as there is substantial computing content and project is predominantly of a
practical, problem-solving nature. You might take up an interest which you already have in
your stream of engineering. You may do your project in any reputed organization or a
department. Every student is to take up a project individually. The project is a vehicle for you
to demonstrate the required level of competence in your chosen field of Masters.
Start thinking about your project right in the beginning. If you want to do the project in
industrial environment start your correspondence fairly early to find an organization, which is
ready to accept you You must submit an outline of your project (two or three pages) to your
guide within one month of start of the project work. This must include the Title, Objective,
Methodology (main steps to carry out a project), expected output and organization where you
intend to carry out the project.
Arranging a Guide
When you have an idea of your project, even a tentative one, approach a suitable person who
has interest and expertise in that area. The Guide may be a person with M.E. / M.Tech with a
five-year working experience or a B.E./ B.Tech having a working experience of fifteen years
in relevant field.
Working with the Guide
The Guide’s role is to provide support and encouragement to direct the student’s attention to
relevant literature, to provide technical assistance occasionally, to read and comment on the
draft report and to give guidance on the standard and amount of work required. The Guide is
not responsible to teach any new skills and language required for project work or for
arranging any literature or equipment. You are expected to meet at least once a month to your
Guide. Rest you can workout your own arrangement. The students, who are content to carry
out their work largely without supervision, should keep their Guide in touch with what they
are doing. A student should not remain silent for months and then appear with a complete
project work unknown to supervisor. In such circumstances, the Guide cannot be counted on
to give an automatic seal of his approval. If a project produces a piece of software, the Guide
would normally expect to see a demonstration of the software in action.
The main purpose of the report is to explain what you did in your project. The reader should
be able to see clearly what you set out to do and what you achieved. It should describe the
problem addresses and explain why you tackled it in the way you did. It should include your
own assessment of how successful the project was.
Resist temptation to include pages of padding. If the project consists of developing an
application in area with which a computer scientist would not be familiar – such as chemical
testing, stock & shares – it might be necessary to include some explanatory company/
organization profile for whom you have done the work must not appear in chapters and must
go to appendix part.
The work that is presented for examiners should be your own. The presentation of another
person’s work, design or program as though they are your own is a serious examination
offence. Direct quotation form the work of others (published or un published) must always be
clearly identified as such by being placed in quotation marks, it is essential that reader should
be able to see where the other work ends and your begins.
Sometimes a project containing good work is marred by a report, which is turgid, obscure and
simply ungrammatical. In such cases, it is very difficult to find out the work done during the
project. An examiner cannot be kind enough to look properly on a project that is almost
unreadable.
Some important points for carrying out a project
1. The organizations or companies offer you a placement for project work out of good
will or to get some useful work done. Usually the companies do not provide you
everything required by you. You must settle this right in the beginning of the project
with the business that what will you get from them and what you have to arrange
yourself.
2. Some times a complication arises due to the fact that some aspect of your project
work is considered confidential by the company. If this is so, it is your responsibility
to get whatever clearance is necessary from the organization right in the beginning as
essential parts like system analysis and design, flow charts etc. can not be missing
from a project report.
3. Make sure you allow enough time for writing report. It is strongly recommended that
do some writing work as you carry out the project rather than leaving write up until
the end. You must allow at least a month to finally write the report. There has to be
enough time for the supervisor to read and comment on it and for student to make
changes (sometimes extensive) on the basis of the comments. You may have to
prepare two or three drafts before the final submission. Remember that it is mainly the
project reports that get examined. An external supervisor receives a pile of project
reports written by people who he does not know. If a project produced some software
he even may not get time to see it running. In most cases he forms his judgment
purely on the basis of the report. Please make your report as readable as possible
content wise as well as presentation wise.
a. Introduction: This must contain background, any previous work done in the area of
your project, your objective and other relevant material that may be helpful to further
explain your project work.
b. The existing system: The study of the present system; problems in existing system.
c. System design: The proposed system; Any specific problem encountered at how you
handled them.
d. Implementation of the system: Implementation issues and their justification.
e. Conclusions: Any shortcoming; your assessment of your work; comparison of your
work with similar works; silent features of your work any feature modification. Real
times applications of your project work.
References must be given at the end following any standard way of giving references.
For example:
Langdrof, ‘Theory of Alternating Current Machinery” Tata McGraw Hill, July 2003.
Finally, your project work is your brainchild and nobody knows about it more than you. Be
confident to explain your work at the time of viva and be honest to accept any short falls.
The Project Report Details
The report should be prepared with the Word Processing software. They should be printed on
A4 size (Executive Bond) paper. A margin of 1.5 inches must be allowed on left hand side
for binding. The pages should be numbered. The report should be typed in the 12-font size
with vertical spacing of 1.5. You must submit three copies of your Project Report in
between 15.06.05 and 20.06.05 positively alongwith a brief Bio –Data of the Supervisor.
A report should be hard bound (light green cover with golden print on the cover). The title of
the project should be clearly visible on the cover.
The cover page should be as figures below. The first page should be title page containing the
title, the candidates name, Enrolment Number, Name of Study Centre and University. Second
page is a certificate from the supervisor. The 3rd page is for the acknowledgement. Fourth
page gives the contents of the project report. Fifth page should be an abstract of the project
followed by the chapters. You must ensure that all pages are legible. Where the project has
produced software for a personal computer, you should include a CD inside the back cover of
the report, along with instructions in the report how to run it.
Reference Books:
Cover Page Project Title
A Project Report
Submitted in partial fulfillment of the degree of Master of
Technology
Supervisor’s Student’s Name Name Karnataka State Open University,
Mysore (Year)
LOGO
Certificate by Supervisor
2
Acknowledgment
3
Contents
4
Abstract
5